Category Archives: astronomy news

The Glory of the Trifid

Star Formation Factory

The Trifid Nebula as seen by the European Southern Observatory Wide-field Imager. Click to embiggen.
The Trifid Nebula as seen by the European Southern Observatory Wide-field Imager. Click to embiggen.

One of the sky sights in the Milky Way that delights summertime stargazers in the Northern Hemisphere (and late winter-early spring gazers in the Southern Hemisphere) is the Trifid Nebula. It lies in the constellation Sagittarius and is a massive stellar factory.  Professional astronomers study it to understand the whys and wherefores of star formation; amateurs just like to look at its gorgeousness.  The European Southern Observatory has just released a new wide-field image of the Trifid that really lets you explore the details of this region, as seen in visible light.

Let’s take a little tour of the image. First, if you can, right-click on the image and open in a separate window.

Now, look at the bluish patch to the upper left. This is what’s known as a reflection nebula. It does what it sounds like it does — the gas in the nebula scatters light from nearby stars that were born in the nebula.  The larger ones shine hotter and brighter, especially in the blue portion of the visible spectrum. Dust grains and molecules scatter blue light more efficiently than red light and that makes this part of the nebula look so very pretty and blue.

The pink-reddish area is a typical emission nebula. That differs from reflection nebula in a very important way — instead of reflecting light, the gases are heated by the hot, young nearby stars and that ultra-hot bath of radiation causes the gases to glow.  They emit the red signature light of hydrogen, which is the major component of the gas.

That’s two kinds of nebula in the scene, but there’s a third type. The gases and dust that crisscross the clouds make up the third kind of nebula. They form what’s called a dark nebula, and they block out the light from the parts of the nebula that lie behind them — similar to the way a dust cloud on Earth blocks out sunlight.  These aren’t dead clouds, however. The remnants of previous rounds of star birth are clumping together and coalescing under the pull of gravity from within.  Eventually, the cloud gets dense and hot enough and the pressure from the coalescence triggers nuclear fusion where the clouds are the thickest — this is the formative event of a newborn star.

Finally, if you look at the lower part of the emission nebula, you can see a finger of gas poking out, pointing directly at the central star powering the Trifid. This is an example of an evaporating gaseous globule, or “EGG”.   At the tip of the finger, which was photographed by Hubble, a knot of dense gas is holding out against the onslaught of radiation from the massive star.

There are star formation sites in many places in our galaxy — and of course, in other other galaxies. Astronomers study them to see how the process of star birth progresses — which, in turn, gives them insight into how our own star formed more than 4.5 billion years ago.

Starving Black Holes and Smashing Planets

Life Sucked for Early Black Holes

Lots of big astronomy news is hitting the ether this afternoon. The first story to catch my eye is this one about how early black holes weren’t quite the gluttons for material that they were expected to be.  Since most galaxies have black holes at their hearts, this idea that the first ones couldn’t get enough to eat in the early universe has profound implications for how astronomers understand galaxy formation.

A computer simulation of x-rays produced by an early black hole and their effects on nearby gas clouds. Early stars ate up most of the gas, leaving little for the resulting black holes to feed on. Courtesy KIPAC/SLAC/M. Alvarez, T. Abel and J. Wise .
A computer simulation of x-rays produced by an early black hole and their effects on nearby gas clouds. Early stars ate up most of the gas, leaving little for the resulting black holes to feed on. Courtesy KIPAC/SLAC/M. Alvarez, T. Abel and J. Wise .

To get a handle on the black hole diet way back in the first million years after the Big Bang, astronomers at the Goddard Space Flight Center and the Kavli Institute for Particle Astrophysics and Cosmology, performed a supercomputer simulation of conditions back when the first stars and galaxies were forming — some 13 billion years ago.

“The first stars were much more massive than most stars we see today, upwards of 100 times the mass of our sun,” said John Wise, a post-doctoral fellow at NASA’s Goddard Space Flight Center in Greenbelt, Md., and one of the study’s authors. “For the first time, we were able to simulate in detail what happens to the gas around those stars before and after they form black holes.”

In the simulation, cosmic gas slowly coalesced under the force of gravity and eventually formed the first nassive, hot stars. They burned brightly for a short time and emitted so much energy in the form of starlight that they pushed away nearby gas clouds.

These stars could not sustain such a fiery existence for long, and they soon exhausted their internal fuel. In the simulation, one of the stars collapsed under its own weight to form a black hole.  since the progenitor star had either consumed or pushed away the rest of the gas cloud, the black hole was essentially “starved” of matter on which to grow.

So, the first black holes were on a pretty strict diet — but they still managed to produce x-ray radiation that kept nearby gas from falling in to the black holes.  This radiational also heated gas a hundred light-years away to several thousand degrees. When you get that kind of heated gas cloud, it can’t coalesce to form new stars — and so even though the black holes were starving, they contributed to the dietary cycle by starving nearby areas of any material from which to form new stars.  How does affect galaxy formation?  Well, starving out the star-formation process affects the growth of galaxies. Yet, we have galaxies now, and we’ve seen galaxies back then — so the next step is to understand how the first galaxies overcame this strict diet inflicted on them by their black holes. Stay tuned!

You can watch a nifty animation of the black hole starvation scenario here.

Planetary Collisions Spotted by Spitzer

Planetary collision -- an artists concept of a stupendous event! (Courtesy NASA/JPL-Caltech)  Click to embiggen.
Planetary collision -- an artist's concept of a stupendous event! (Courtesy NASA/JPL-Caltech) Click to embiggen.

The other big story today that caught my attention is the infamous colliding planets announcement. Now, my friend Phil Plait over at BadAstronomy wrote a book called Death from the Skies that talks about all the ways we can die (or be seriously inconvenienced) by the cosmos — but I don’t think he covered colliding planets. Now that Spitzer Space Telescope has caught evidence of planets colliding around another star, he can add that one in to the next edition of the book.

So, what’s the story behind this discovery?

NASA’s Spitzer Space Telescope found evidence that a high-speed collision between two forming planets — one about the size of Mercury and the other about the size of our Moon —  occurred a few thousand years ago around a young star, called HD 172555.  This planetary system, which is about 100 light-years away from us, is still in the early stages of planet formation.

So, what evidence did Spitzer capture of this dramatic event?  When the collision occurred, lots of vaporized, melted rock and bits of rubble got thrown across immediate space. As you can imagine, such a collision causes lots of heat — and the infrared heat signature is something that Spitzer is especially good at detecting.

As the bodies slammed into each other at speeds upwards of 10 kilometers a second, a huge flash of light would have been emitted. Rocky surfaces were vaporized and melted, and hot matter was sprayed everywhere. Spitzer detected the vaporized rock in the form of silicon monoxide gas, and the melted rock as a glassy substance called obsidian. On Earth, obsidian can be found around volcanoes, and in black rocks called tektites often found around meteor craters.

At the end of the collision process, the larger planet was essentially stripped of its outer layers. It absorbed the core and most of the surface material of the smaller body. This is likely how Earth formed — by collision and accretion, some 4 billion years ago.  It’s probably very similar to how Mercury formed, and a similar collision contributed to the formation of our Moon. So, in a sense, the Spitzer observations are giving astronomers a very interesting look back to the birth of our own solar system.